[libfirm] / ir / be / sparc / sparc_transform.c

/*
 * Copyright (C) 1995-2010 University of Karlsruhe.  All right reserved.
 *
 * This file is part of libFirm.
 *
 * This file may be distributed and/or modified under the terms of the
 * GNU General Public License version 2 as published by the Free Software
 * Foundation and appearing in the file LICENSE.GPL included in the
 * packaging of this file.
 *
 * Licensees holding valid libFirm Professional Edition licenses may use
 * this file in accordance with the libFirm Commercial License.
 * Agreement provided with the Software.
 *
 * This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE
 * WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 * PURPOSE.
 */

/**
 * @file
 * @brief   code selection (transform FIRM into SPARC FIRM)
 * @author  Hannes Rapp, Matthias Braun
 */
#include "config.h"

#include <stdint.h>
#include <stdbool.h>

#include "irnode_t.h"
#include "irgraph_t.h"
#include "irmode_t.h"
#include "irgmod.h"
#include "iredges.h"
#include "ircons.h"
#include "irprintf.h"
#include "iroptimize.h"
#include "dbginfo.h"
#include "iropt_t.h"
#include "debug.h"
#include "error.h"
#include "util.h"

#include "benode.h"
#include "beirg.h"
#include "beutil.h"
#include "betranshlp.h"
#include "beabihelper.h"
#include "bearch_sparc_t.h"

#include "sparc_nodes_attr.h"
#include "sparc_transform.h"
#include "sparc_new_nodes.h"
#include "gen_sparc_new_nodes.h"

#include "gen_sparc_regalloc_if.h"
#include "sparc_cconv.h"

#include <limits.h>

DEBUG_ONLY(static firm_dbg_module_t *dbg = NULL;)

static const arch_register_t *sp_reg = &sparc_registers[REG_SP];
static const arch_register_t *fp_reg = &sparc_registers[REG_FRAME_POINTER];
static calling_convention_t  *current_cconv = NULL;
static be_stackorder_t       *stackorder;
static ir_mode               *mode_gp;
static ir_mode               *mode_flags;
static ir_mode               *mode_fp;
static ir_mode               *mode_fp2;
//static ir_mode               *mode_fp4;
static pmap                  *node_to_stack;
static size_t                 start_mem_offset;
static ir_node               *start_mem;
static size_t                 start_g0_offset;
static ir_node               *start_g0;
static size_t                 start_g7_offset;
static ir_node               *start_g7;
static size_t                 start_sp_offset;
static ir_node               *start_sp;
static size_t                 start_fp_offset;
static ir_node               *start_fp;
static ir_node               *frame_base;
static size_t                 start_params_offset;
static size_t                 start_callee_saves_offset;

static const arch_register_t *const omit_fp_callee_saves[] = {
        &sparc_registers[REG_L0],
        &sparc_registers[REG_L1],
        &sparc_registers[REG_L2],
        &sparc_registers[REG_L3],
        &sparc_registers[REG_L4],
        &sparc_registers[REG_L5],
        &sparc_registers[REG_L6],
        &sparc_registers[REG_L7],
        &sparc_registers[REG_I0],
        &sparc_registers[REG_I1],
        &sparc_registers[REG_I2],
        &sparc_registers[REG_I3],
        &sparc_registers[REG_I4],
        &sparc_registers[REG_I5],
};

static inline bool mode_needs_gp_reg(ir_mode *mode)
{
        if (mode_is_int(mode) || mode_is_reference(mode)) {
                /* we should only see 32bit code */
                assert(get_mode_size_bits(mode) <= 32);
                return true;
        }
        return false;
}

/**
 * Create an And that will zero out upper bits.
 *
 * @param dbgi      debug info
 * @param block     the basic block
 * @param op        the original node
 * @param src_bits  number of lower bits that will remain
 */
static ir_node *gen_zero_extension(dbg_info *dbgi, ir_node *block, ir_node *op,
                                   int src_bits)
{
        if (src_bits == 8) {
                return new_bd_sparc_And_imm(dbgi, block, op, NULL, 0xFF);
        } else if (src_bits == 16) {
                ir_node *lshift = new_bd_sparc_Sll_imm(dbgi, block, op, NULL, 16);
                ir_node *rshift = new_bd_sparc_Srl_imm(dbgi, block, lshift, NULL, 16);
                return rshift;
        } else {
                panic("zero extension only supported for 8 and 16 bits");
        }
}

/**
 * Generate code for a sign extension.
 *
 * @param dbgi      debug info
 * @param block     the basic block
 * @param op        the original node
 * @param src_bits  number of lower bits that will remain
 */
static ir_node *gen_sign_extension(dbg_info *dbgi, ir_node *block, ir_node *op,
                                   int src_bits)
{
        int shift_width = 32 - src_bits;
        ir_node *lshift_node = new_bd_sparc_Sll_imm(dbgi, block, op, NULL, shift_width);
        ir_node *rshift_node = new_bd_sparc_Sra_imm(dbgi, block, lshift_node, NULL, shift_width);
        return rshift_node;
}

/**
 * returns true if it is assured, that the upper bits of a node are "clean"
 * which means for a 16 or 8 bit value, that the upper bits in the register
 * are 0 for unsigned and a copy of the last significant bit for signed
 * numbers.
 */
static bool upper_bits_clean(ir_node *node, ir_mode *mode)
{
        switch ((ir_opcode)get_irn_opcode(node)) {
        case iro_And:
                if (!mode_is_signed(mode)) {
                        return upper_bits_clean(get_And_left(node), mode)
                            || upper_bits_clean(get_And_right(node), mode);
                }
                /* FALLTHROUGH */
        case iro_Or:
        case iro_Eor:
                return upper_bits_clean(get_binop_left(node), mode)
                    && upper_bits_clean(get_binop_right(node), mode);

        case iro_Shr:
                if (mode_is_signed(mode)) {
                        return false; /* TODO */
                } else {
                        ir_node *right = get_Shr_right(node);
                        if (is_Const(right)) {
                                ir_tarval *tv  = get_Const_tarval(right);
                                long       val = get_tarval_long(tv);
                                if (val >= 32 - (long)get_mode_size_bits(mode))
                                        return true;
                        }
                        return upper_bits_clean(get_Shr_left(node), mode);
                }

        case iro_Shrs:
                return upper_bits_clean(get_Shrs_left(node), mode);

        case iro_Const: {
                ir_tarval *tv  = get_Const_tarval(node);
                long       val = get_tarval_long(tv);
                if (mode_is_signed(mode)) {
                        long    shifted = val >> (get_mode_size_bits(mode)-1);
                        return shifted == 0 || shifted == -1;
                } else {
                        unsigned long shifted = (unsigned long)val;
                        shifted >>= get_mode_size_bits(mode)-1;
                        shifted >>= 1;
                        return shifted == 0;
                }
        }

        case iro_Conv: {
                ir_mode *dest_mode = get_irn_mode(node);
                ir_node *op        = get_Conv_op(node);
                ir_mode *src_mode  = get_irn_mode(op);
                unsigned src_bits  = get_mode_size_bits(src_mode);
                unsigned dest_bits = get_mode_size_bits(dest_mode);
                /* downconvs are a nop */
                if (src_bits <= dest_bits)
                        return upper_bits_clean(op, mode);
                if (dest_bits <= get_mode_size_bits(mode)
                    && mode_is_signed(dest_mode) == mode_is_signed(mode))
                        return true;
                return false;
        }

        case iro_Proj: {
                ir_node *pred = get_Proj_pred(node);
                switch (get_irn_opcode(pred)) {
                case iro_Load: {
                        ir_mode *load_mode = get_Load_mode(pred);
                        unsigned load_bits = get_mode_size_bits(load_mode);
                        unsigned bits      = get_mode_size_bits(mode);
                        if (load_bits > bits)
                                return false;
                        if (mode_is_signed(mode) != mode_is_signed(load_mode))
                                return false;
                        return true;
                }
                default:
                        break;
                }
        }
        default:
                break;
        }
        return false;
}

/**
 * Extend a value to 32 bit signed/unsigned depending on its mode.
 *
 * @param dbgi      debug info
 * @param block     the basic block
 * @param op        the original node
 * @param orig_mode the original mode of op
 */
static ir_node *gen_extension(dbg_info *dbgi, ir_node *block, ir_node *op,
                              ir_mode *orig_mode)
{
        int bits = get_mode_size_bits(orig_mode);
        assert(bits < 32);

        if (mode_is_signed(orig_mode)) {
                return gen_sign_extension(dbgi, block, op, bits);
        } else {
                return gen_zero_extension(dbgi, block, op, bits);
        }
}

typedef enum {
        MATCH_NONE         = 0,
        MATCH_COMMUTATIVE  = 1U << 0, /**< commutative operation. */
        MATCH_MODE_NEUTRAL = 1U << 1, /**< the higher bits of the inputs don't
                                           influence the significant lower bit at
                                           all (for cases where mode < 32bit) */
} match_flags_t;
ENUM_BITSET(match_flags_t)

typedef ir_node* (*new_binop_reg_func) (dbg_info *dbgi, ir_node *block, ir_node *op1, ir_node *op2);
typedef ir_node* (*new_binop_fp_func) (dbg_info *dbgi, ir_node *block, ir_node *op1, ir_node *op2, ir_mode *mode);
typedef ir_node* (*new_binop_imm_func) (dbg_info *dbgi, ir_node *block, ir_node *op1, ir_entity *entity, int32_t immediate);
typedef ir_node* (*new_unop_fp_func) (dbg_info *dbgi, ir_node *block, ir_node *op1, ir_mode *mode);

/**
 * checks if a node's value can be encoded as a immediate
 */
static bool is_imm_encodeable(const ir_node *node)
{
        long value;
        if (!is_Const(node))
                return false;

        value = get_tarval_long(get_Const_tarval(node));
        return sparc_is_value_imm_encodeable(value);
}

static bool needs_extension(ir_node *op)
{
        ir_mode *mode = get_irn_mode(op);
        if (get_mode_size_bits(mode) >= get_mode_size_bits(mode_gp))
                return false;
        return !upper_bits_clean(op, mode);
}

/**
 * Check, if a given node is a Down-Conv, ie. a integer Conv
 * from a mode with a mode with more bits to a mode with lesser bits.
 * Moreover, we return only true if the node has not more than 1 user.
 *
 * @param node   the node
 * @return non-zero if node is a Down-Conv
 */
static bool is_downconv(const ir_node *node)
{
        ir_mode *src_mode;
        ir_mode *dest_mode;

        if (!is_Conv(node))
                return false;

        src_mode  = get_irn_mode(get_Conv_op(node));
        dest_mode = get_irn_mode(node);
        return
                mode_needs_gp_reg(src_mode)  &&
                mode_needs_gp_reg(dest_mode) &&
                get_mode_size_bits(dest_mode) <= get_mode_size_bits(src_mode);
}

static ir_node *skip_downconv(ir_node *node)
{
        while (is_downconv(node)) {
                node = get_Conv_op(node);
        }
        return node;
}

/**
 * helper function for binop operations
 *
 * @param new_reg  register generation function ptr
 * @param new_imm  immediate generation function ptr
 */
static ir_node *gen_helper_binop_args(ir_node *node,
                                      ir_node *op1, ir_node *op2,
                                      match_flags_t flags,
                                      new_binop_reg_func new_reg,
                                      new_binop_imm_func new_imm)
{
        dbg_info *dbgi  = get_irn_dbg_info(node);
        ir_node  *block = be_transform_node(get_nodes_block(node));
        ir_node  *new_op1;
        ir_node  *new_op2;
        ir_mode  *mode1;
        ir_mode  *mode2;

        if (flags & MATCH_MODE_NEUTRAL) {
                op1 = skip_downconv(op1);
                op2 = skip_downconv(op2);
        }
        mode1 = get_irn_mode(op1);
        mode2 = get_irn_mode(op2);
        /* we shouldn't see 64bit code */
        assert(get_mode_size_bits(mode1) <= 32);
        assert(get_mode_size_bits(mode2) <= 32);

        if (is_imm_encodeable(op2)) {
                int32_t  immediate = get_tarval_long(get_Const_tarval(op2));
                new_op1 = be_transform_node(op1);
                if (! (flags & MATCH_MODE_NEUTRAL) && needs_extension(op1)) {
                        new_op1 = gen_extension(dbgi, block, new_op1, mode1);
                }
                return new_imm(dbgi, block, new_op1, NULL, immediate);
        }
        new_op2 = be_transform_node(op2);
        if (! (flags & MATCH_MODE_NEUTRAL) && needs_extension(op2)) {
                new_op2 = gen_extension(dbgi, block, new_op2, mode2);
        }

        if ((flags & MATCH_COMMUTATIVE) && is_imm_encodeable(op1)) {
                int32_t immediate = get_tarval_long(get_Const_tarval(op1));
                return new_imm(dbgi, block, new_op2, NULL, immediate);
        }

        new_op1 = be_transform_node(op1);
        if (! (flags & MATCH_MODE_NEUTRAL) && needs_extension(op1)) {
                new_op1 = gen_extension(dbgi, block, new_op1, mode1);
        }
        return new_reg(dbgi, block, new_op1, new_op2);
}

static ir_node *gen_helper_binop(ir_node *node, match_flags_t flags,
                                 new_binop_reg_func new_reg,
                                 new_binop_imm_func new_imm)
{
        ir_node *op1 = get_binop_left(node);
        ir_node *op2 = get_binop_right(node);
        return gen_helper_binop_args(node, op1, op2, flags, new_reg, new_imm);
}

/**
 * helper function for FP binop operations
 */
static ir_node *gen_helper_binfpop(ir_node *node, ir_mode *mode,
                                   new_binop_fp_func new_func_single,
                                   new_binop_fp_func new_func_double,
                                   new_binop_fp_func new_func_quad)
{
        ir_node  *block   = be_transform_node(get_nodes_block(node));
        ir_node  *op1     = get_binop_left(node);
        ir_node  *new_op1 = be_transform_node(op1);
        ir_node  *op2     = get_binop_right(node);
        ir_node  *new_op2 = be_transform_node(op2);
        dbg_info *dbgi    = get_irn_dbg_info(node);
        unsigned  bits    = get_mode_size_bits(mode);

        switch (bits) {
        case 32:
                return new_func_single(dbgi, block, new_op1, new_op2, mode);
        case 64:
                return new_func_double(dbgi, block, new_op1, new_op2, mode);
        case 128:
                return new_func_quad(dbgi, block, new_op1, new_op2, mode);
        default:
                break;
        }
        panic("unsupported mode %+F for float op", mode);
}

static ir_node *gen_helper_unfpop(ir_node *node, ir_mode *mode,
                                  new_unop_fp_func new_func_single,
                                  new_unop_fp_func new_func_double,
                                  new_unop_fp_func new_func_quad)
{
        ir_node  *block  = be_transform_node(get_nodes_block(node));
        ir_node  *op     = get_unop_op(node);
        ir_node  *new_op = be_transform_node(op);
        dbg_info *dbgi   = get_irn_dbg_info(node);
        unsigned  bits   = get_mode_size_bits(mode);

        switch (bits) {
        case 32:
                return new_func_single(dbgi, block, new_op, mode);
        case 64:
                return new_func_double(dbgi, block, new_op, mode);
        case 128:
                return new_func_quad(dbgi, block, new_op, mode);
        default:
                break;
        }
        panic("unsupported mode %+F for float op", mode);
}

typedef ir_node* (*new_binopx_imm_func)(dbg_info *dbgi, ir_node *block,
                                        ir_node *op1, ir_node *flags,
                                        ir_entity *imm_entity, int32_t imm);

typedef ir_node* (*new_binopx_reg_func)(dbg_info *dbgi, ir_node *block,
                                        ir_node *op1, ir_node *op2,
                                        ir_node *flags);

static ir_node *gen_helper_binopx(ir_node *node, match_flags_t match_flags,
                                  new_binopx_reg_func new_binopx_reg,
                                  new_binopx_imm_func new_binopx_imm)
{
        dbg_info *dbgi      = get_irn_dbg_info(node);
        ir_node  *block     = be_transform_node(get_nodes_block(node));
        ir_node  *op1       = get_irn_n(node, 0);
        ir_node  *op2       = get_irn_n(node, 1);
        ir_node  *flags     = get_irn_n(node, 2);
        ir_node  *new_flags = be_transform_node(flags);
        ir_node  *new_op1;
        ir_node  *new_op2;

        /* only support for mode-neutral implemented so far */
        assert(match_flags & MATCH_MODE_NEUTRAL);

        if (is_imm_encodeable(op2)) {
                int32_t  immediate = get_tarval_long(get_Const_tarval(op2));
                new_op1 = be_transform_node(op1);
                return new_binopx_imm(dbgi, block, new_op1, new_flags, NULL, immediate);
        }
        new_op2 = be_transform_node(op2);
        if ((match_flags & MATCH_COMMUTATIVE) && is_imm_encodeable(op1)) {
                int32_t immediate = get_tarval_long(get_Const_tarval(op1));
                return new_binopx_imm(dbgi, block, new_op2, new_flags, NULL, immediate);
        }
        new_op1 = be_transform_node(op1);
        return new_binopx_reg(dbgi, block, new_op1, new_op2, new_flags);

}

static ir_node *get_g0(ir_graph *irg)
{
        if (start_g0 == NULL) {
                /* this is already the transformed start node */
                ir_node *start = get_irg_start(irg);
                assert(is_sparc_Start(start));
                start_g0 = new_r_Proj(start, mode_gp, start_g0_offset);
        }
        return start_g0;
}

static ir_node *get_g7(ir_graph *irg)
{
        if (start_g7 == NULL) {
                ir_node *start = get_irg_start(irg);
                assert(is_sparc_Start(start));
                start_g7 = new_r_Proj(start, mode_gp, start_g7_offset);
        }
        return start_g7;
}

static ir_node *make_tls_offset(dbg_info *dbgi, ir_node *block,
                                ir_entity *entity, int32_t offset)
{
        ir_node  *hi  = new_bd_sparc_SetHi(dbgi, block, entity, offset);
        ir_node  *low = new_bd_sparc_Xor_imm(dbgi, block, hi, entity, offset);
        return low;
}

static ir_node *make_address(dbg_info *dbgi, ir_node *block, ir_entity *entity,
                             int32_t offset)
{
        if (get_entity_owner(entity) == get_tls_type()) {
                ir_graph *irg     = get_irn_irg(block);
                ir_node  *g7      = get_g7(irg);
                ir_node  *offsetn = make_tls_offset(dbgi, block, entity, offset);
                ir_node  *add     = new_bd_sparc_Add_reg(dbgi, block, g7, offsetn);
                return add;
        } else {
                ir_node *hi  = new_bd_sparc_SetHi(dbgi, block, entity, offset);
                ir_node *low = new_bd_sparc_Or_imm(dbgi, block, hi, entity, offset);
                return low;
        }
}

typedef struct address_t {
        ir_node   *ptr;
        ir_node   *ptr2;
        ir_entity *entity;
        int32_t    offset;
} address_t;

/**
 * Match a load/store address
 */
static void match_address(ir_node *ptr, address_t *address, bool use_ptr2)
{
        ir_node   *base   = ptr;
        ir_node   *ptr2   = NULL;
        int32_t    offset = 0;
        ir_entity *entity = NULL;

        if (is_Add(base)) {
                ir_node *add_right = get_Add_right(base);
                if (is_Const(add_right)) {
                        base    = get_Add_left(base);
                        offset += get_tarval_long(get_Const_tarval(add_right));
                }
        }
        /* Note that we don't match sub(x, Const) or chains of adds/subs
         * because this should all be normalized by now */

        /* we only use the symconst if we're the only user otherwise we probably
         * won't save anything but produce multiple sethi+or combinations with
         * just different offsets */
        if (is_SymConst(base) && get_irn_n_edges(base) == 1) {
                ir_entity *sc_entity = get_SymConst_entity(base);
                dbg_info  *dbgi      = get_irn_dbg_info(ptr);
                ir_node   *block     = get_nodes_block(ptr);
                ir_node   *new_block = be_transform_node(block);

                if (get_entity_owner(sc_entity) == get_tls_type()) {
                        if (!use_ptr2) {
                                goto only_offset;
                        } else {
                                ptr2   = make_tls_offset(dbgi, new_block, sc_entity, offset);
                                offset = 0;
                                base   = get_g7(get_irn_irg(base));
                        }
                } else {
                        entity = sc_entity;
                        base   = new_bd_sparc_SetHi(dbgi, new_block, entity, offset);
                }
        } else if (use_ptr2 && is_Add(base) && offset == 0) {
                ptr2 = be_transform_node(get_Add_right(base));
                base = be_transform_node(get_Add_left(base));
        } else {
only_offset:
                if (sparc_is_value_imm_encodeable(offset)) {
                        base = be_transform_node(base);
                } else {
                        base   = be_transform_node(ptr);
                        offset = 0;
                }
        }

        address->ptr    = base;
        address->ptr2   = ptr2;
        address->entity = entity;
        address->offset = offset;
}

/**
 * Creates an sparc Add.
 *
 * @param node   FIRM node
 * @return the created sparc Add node
 */
static ir_node *gen_Add(ir_node *node)
{
        ir_mode *mode = get_irn_mode(node);
        ir_node *right;

        if (mode_is_float(mode)) {
                return gen_helper_binfpop(node, mode, new_bd_sparc_fadd_s,
                                          new_bd_sparc_fadd_d, new_bd_sparc_fadd_q);
        }

        /* special case: + 0x1000 can be represented as - 0x1000 */
        right = get_Add_right(node);
        if (is_Const(right)) {
                ir_node   *left = get_Add_left(node);
                ir_tarval *tv;
                uint32_t   val;
                /* is this simple address arithmetic? then we can let the linker do
                 * the calculation. */
                if (is_SymConst(left) && get_irn_n_edges(left) == 1) {
                        dbg_info *dbgi  = get_irn_dbg_info(node);
                        ir_node  *block = be_transform_node(get_nodes_block(node));
                        address_t address;

                        /* the value of use_ptr2 shouldn't matter here */
                        match_address(node, &address, false);
                        assert(is_sparc_SetHi(address.ptr));
                        return new_bd_sparc_Or_imm(dbgi, block, address.ptr,
                                                   address.entity, address.offset);
                }

                tv  = get_Const_tarval(right);
                val = get_tarval_long(tv);
                if (val == 0x1000) {
                        dbg_info *dbgi   = get_irn_dbg_info(node);
                        ir_node  *block  = be_transform_node(get_nodes_block(node));
                        ir_node  *op     = get_Add_left(node);
                        ir_node  *new_op = be_transform_node(op);
                        return new_bd_sparc_Sub_imm(dbgi, block, new_op, NULL, -0x1000);
                }
        }

        return gen_helper_binop(node, MATCH_COMMUTATIVE | MATCH_MODE_NEUTRAL,
                                new_bd_sparc_Add_reg, new_bd_sparc_Add_imm);
}

static ir_node *gen_AddCC_t(ir_node *node)
{
        return gen_helper_binop(node, MATCH_COMMUTATIVE | MATCH_MODE_NEUTRAL,
                                new_bd_sparc_AddCC_reg, new_bd_sparc_AddCC_imm);
}

static ir_node *gen_Proj_AddCC_t(ir_node *node)
{
        long     pn       = get_Proj_proj(node);
        ir_node *pred     = get_Proj_pred(node);
        ir_node *new_pred = be_transform_node(pred);

        switch (pn) {
        case pn_sparc_AddCC_t_res:
                return new_r_Proj(new_pred, mode_gp, pn_sparc_AddCC_res);
        case pn_sparc_AddCC_t_flags:
                return new_r_Proj(new_pred, mode_flags, pn_sparc_AddCC_flags);
        default:
                panic("Invalid AddCC_t proj found");
        }
}

static ir_node *gen_AddX_t(ir_node *node)
{
        return gen_helper_binopx(node, MATCH_COMMUTATIVE | MATCH_MODE_NEUTRAL,
                                 new_bd_sparc_AddX_reg, new_bd_sparc_AddX_imm);
}

/**
 * Creates an sparc Sub.
 *
 * @param node       FIRM node
 * @return the created sparc Sub node
 */
static ir_node *gen_Sub(ir_node *node)
{
        ir_mode *mode = get_irn_mode(node);

        if (mode_is_float(mode)) {
                return gen_helper_binfpop(node, mode, new_bd_sparc_fsub_s,
                                          new_bd_sparc_fsub_d, new_bd_sparc_fsub_q);
        }

        return gen_helper_binop(node, MATCH_MODE_NEUTRAL,
                                new_bd_sparc_Sub_reg, new_bd_sparc_Sub_imm);
}

static ir_node *gen_SubCC_t(ir_node *node)
{
        return gen_helper_binop(node, MATCH_MODE_NEUTRAL,
                                new_bd_sparc_SubCC_reg, new_bd_sparc_SubCC_imm);
}

static ir_node *gen_Proj_SubCC_t(ir_node *node)
{
        long     pn       = get_Proj_proj(node);
        ir_node *pred     = get_Proj_pred(node);
        ir_node *new_pred = be_transform_node(pred);

        switch (pn) {
        case pn_sparc_SubCC_t_res:
                return new_r_Proj(new_pred, mode_gp, pn_sparc_SubCC_res);
        case pn_sparc_SubCC_t_flags:
                return new_r_Proj(new_pred, mode_flags, pn_sparc_SubCC_flags);
        default:
                panic("Invalid SubCC_t proj found");
        }
}

static ir_node *gen_SubX_t(ir_node *node)
{
        return gen_helper_binopx(node, MATCH_MODE_NEUTRAL,
                                 new_bd_sparc_SubX_reg, new_bd_sparc_SubX_imm);
}

ir_node *create_ldf(dbg_info *dbgi, ir_node *block, ir_node *ptr,
                    ir_node *mem, ir_mode *mode, ir_entity *entity,
                    long offset, bool is_frame_entity)
{
        unsigned bits = get_mode_size_bits(mode);
        assert(mode_is_float(mode));
        if (bits == 32) {
                return new_bd_sparc_Ldf_s(dbgi, block, ptr, mem, mode, entity,
                                          offset, is_frame_entity);
        } else if (bits == 64) {
                return new_bd_sparc_Ldf_d(dbgi, block, ptr, mem, mode, entity,
                                          offset, is_frame_entity);
        } else {
                assert(bits == 128);
                return new_bd_sparc_Ldf_q(dbgi, block, ptr, mem, mode, entity,
                                          offset, is_frame_entity);
        }
}

ir_node *create_stf(dbg_info *dbgi, ir_node *block, ir_node *value,
                    ir_node *ptr, ir_node *mem, ir_mode *mode,
                    ir_entity *entity, long offset,
                    bool is_frame_entity)
{
        unsigned bits = get_mode_size_bits(mode);
        assert(mode_is_float(mode));
        if (bits == 32) {
                return new_bd_sparc_Stf_s(dbgi, block, value, ptr, mem, mode, entity,
                                          offset, is_frame_entity);
        } else if (bits == 64) {
                return new_bd_sparc_Stf_d(dbgi, block, value, ptr, mem, mode, entity,
                                          offset, is_frame_entity);
        } else {
                assert(bits == 128);
                return new_bd_sparc_Stf_q(dbgi, block, value, ptr, mem, mode, entity,
                                          offset, is_frame_entity);
        }
}

/**
 * Transforms a Load.
 *
 * @param node    the ir Load node
 * @return the created sparc Load node
 */
static ir_node *gen_Load(ir_node *node)
{
        dbg_info *dbgi     = get_irn_dbg_info(node);
        ir_mode  *mode     = get_Load_mode(node);
        ir_node  *block    = be_transform_node(get_nodes_block(node));
        ir_node  *ptr      = get_Load_ptr(node);
        ir_node  *mem      = get_Load_mem(node);
        ir_node  *new_mem  = be_transform_node(mem);
        ir_node  *new_load = NULL;
        address_t address;

        if (get_Load_unaligned(node) == align_non_aligned) {
                panic("sparc: transformation of unaligned Loads not implemented yet");
        }

        if (mode_is_float(mode)) {
                match_address(ptr, &address, false);
                new_load = create_ldf(dbgi, block, address.ptr, new_mem, mode,
                                      address.entity, address.offset, false);
        } else {
                match_address(ptr, &address, true);
                if (address.ptr2 != NULL) {
                        assert(address.entity == NULL && address.offset == 0);
                        new_load = new_bd_sparc_Ld_reg(dbgi, block, address.ptr,
                                                       address.ptr2, new_mem, mode);
                } else {
                        new_load = new_bd_sparc_Ld_imm(dbgi, block, address.ptr, new_mem,
                                                       mode, address.entity, address.offset,
                                                       false);
                }
        }
        set_irn_pinned(new_load, get_irn_pinned(node));

        return new_load;
}

/**
 * Transforms a Store.
 *
 * @param node    the ir Store node
 * @return the created sparc Store node
 */
static ir_node *gen_Store(ir_node *node)
{
        ir_node  *block    = be_transform_node(get_nodes_block(node));
        ir_node  *ptr      = get_Store_ptr(node);
        ir_node  *mem      = get_Store_mem(node);
        ir_node  *new_mem  = be_transform_node(mem);
        ir_node  *val      = get_Store_value(node);
        ir_mode  *mode     = get_irn_mode(val);
        dbg_info *dbgi     = get_irn_dbg_info(node);
        ir_node  *new_store = NULL;
        address_t address;

        if (get_Store_unaligned(node) == align_non_aligned) {
                panic("sparc: transformation of unaligned Stores not implemented yet");
        }

        if (mode_is_float(mode)) {
                ir_node *new_val = be_transform_node(val);
                /* TODO: variants with reg+reg address mode */
                match_address(ptr, &address, false);
                new_store = create_stf(dbgi, block, new_val, address.ptr, new_mem,
                                       mode, address.entity, address.offset, false);
        } else {
                ir_node *new_val;
                unsigned dest_bits = get_mode_size_bits(mode);
                while (is_downconv(node)
                       && get_mode_size_bits(get_irn_mode(node)) >= dest_bits) {
                    val = get_Conv_op(val);
                }
                new_val = be_transform_node(val);

                assert(dest_bits <= 32);
                match_address(ptr, &address, true);
                if (address.ptr2 != NULL) {
                        assert(address.entity == NULL && address.offset == 0);
                        new_store = new_bd_sparc_St_reg(dbgi, block, new_val, address.ptr,
                                                        address.ptr2, new_mem, mode);
                } else {
                        new_store = new_bd_sparc_St_imm(dbgi, block, new_val, address.ptr,
                                                        new_mem, mode, address.entity,
                                                        address.offset, false);
                }
        }
        set_irn_pinned(new_store, get_irn_pinned(node));

        return new_store;
}

/**
 * Creates an sparc Mul.
 * returns the lower 32bits of the 64bit multiply result
 *
 * @return the created sparc Mul node
 */
static ir_node *gen_Mul(ir_node *node)
{
        ir_mode *mode = get_irn_mode(node);
        if (mode_is_float(mode)) {
                return gen_helper_binfpop(node, mode, new_bd_sparc_fmul_s,
                                          new_bd_sparc_fmul_d, new_bd_sparc_fmul_q);
        }

        return gen_helper_binop(node, MATCH_COMMUTATIVE | MATCH_MODE_NEUTRAL,
                                new_bd_sparc_Mul_reg, new_bd_sparc_Mul_imm);
}

/**
 * Creates an sparc Mulh.
 * Mulh returns the upper 32bits of a mul instruction
 *
 * @return the created sparc Mulh node
 */
static ir_node *gen_Mulh(ir_node *node)
{
        ir_mode *mode = get_irn_mode(node);
        ir_node *mul;

        if (mode_is_float(mode))
                panic("FP not supported yet");

        if (mode_is_signed(mode)) {
                mul = gen_helper_binop(node, MATCH_COMMUTATIVE, new_bd_sparc_SMulh_reg, new_bd_sparc_SMulh_imm);
                return new_r_Proj(mul, mode_gp, pn_sparc_SMulh_low);
        } else {
                mul = gen_helper_binop(node, MATCH_COMMUTATIVE, new_bd_sparc_UMulh_reg, new_bd_sparc_UMulh_imm);
                return new_r_Proj(mul, mode_gp, pn_sparc_UMulh_low);
        }
}

static ir_node *gen_sign_extension_value(ir_node *node)
{
        ir_node *block     = get_nodes_block(node);
        ir_node *new_block = be_transform_node(block);
        ir_node *new_node  = be_transform_node(node);
        /* TODO: we could do some shortcuts for some value types probably.
         * (For constants or other cases where we know the sign bit in
         *  advance) */
        return new_bd_sparc_Sra_imm(NULL, new_block, new_node, NULL, 31);
}

/**
 * Creates an sparc Div.
 *
 * @return the created sparc Div node
 */
static ir_node *gen_Div(ir_node *node)
{
        dbg_info *dbgi      = get_irn_dbg_info(node);
        ir_node  *block     = get_nodes_block(node);
        ir_node  *new_block = be_transform_node(block);
        ir_mode  *mode      = get_Div_resmode(node);
        ir_node  *left      = get_Div_left(node);
        ir_node  *left_low  = be_transform_node(left);
        ir_node  *right     = get_Div_right(node);
        ir_node  *res;

        if (mode_is_float(mode)) {
                return gen_helper_binfpop(node, mode, new_bd_sparc_fdiv_s,
                                                                  new_bd_sparc_fdiv_d, new_bd_sparc_fdiv_q);
        }

        if (mode_is_signed(mode)) {
                ir_node *left_high = gen_sign_extension_value(left);

                if (is_imm_encodeable(right)) {
                        int32_t immediate = get_tarval_long(get_Const_tarval(right));
                        res = new_bd_sparc_SDiv_imm(dbgi, new_block, left_high, left_low,
                                                    NULL, immediate);
                } else {
                        ir_node *new_right = be_transform_node(right);
                        res = new_bd_sparc_SDiv_reg(dbgi, new_block, left_high, left_low,
                                                    new_right);
                }
        } else {
                ir_graph *irg       = get_irn_irg(node);
                ir_node  *left_high = get_g0(irg);
                if (is_imm_encodeable(right)) {
                        int32_t immediate = get_tarval_long(get_Const_tarval(right));
                        res = new_bd_sparc_UDiv_imm(dbgi, new_block, left_high, left_low,
                                                    NULL, immediate);
                } else {
                        ir_node *new_right = be_transform_node(right);
                        res = new_bd_sparc_UDiv_reg(dbgi, new_block, left_high, left_low,
                                                    new_right);
                }
        }

        return res;
}

/**
 * Transforms a Not node.
 *
 * @return the created sparc Not node
 */
static ir_node *gen_Not(ir_node *node)
{
        ir_node  *op     = get_Not_op(node);
        ir_graph *irg    = get_irn_irg(node);
        ir_node  *zero   = get_g0(irg);
        dbg_info *dbgi   = get_irn_dbg_info(node);
        ir_node  *block  = be_transform_node(get_nodes_block(node));
        ir_node  *new_op = be_transform_node(op);

        /* Note: Not(Eor()) is normalize in firm localopts already so
         * we don't match it for xnor here */

        /* Not can be represented with xnor 0, n */
        return new_bd_sparc_XNor_reg(dbgi, block, zero, new_op);
}

static ir_node *gen_helper_bitop(ir_node *node,
                                 new_binop_reg_func new_reg,
                                 new_binop_imm_func new_imm,
                                 new_binop_reg_func new_not_reg,
                                 new_binop_imm_func new_not_imm,
                                 match_flags_t flags)
{
        ir_node *op1 = get_binop_left(node);
        ir_node *op2 = get_binop_right(node);
        if (is_Not(op1)) {
                return gen_helper_binop_args(node, op2, get_Not_op(op1),
                                             flags,
                                             new_not_reg, new_not_imm);
        }
        if (is_Not(op2)) {
                return gen_helper_binop_args(node, op1, get_Not_op(op2),
                                             flags,
                                             new_not_reg, new_not_imm);
        }
        if (is_Const(op2) && get_irn_n_edges(op2) == 1) {
                ir_tarval *tv    = get_Const_tarval(op2);
                long       value = get_tarval_long(tv);
                if (!sparc_is_value_imm_encodeable(value)) {
                        long notvalue = ~value;
                        if ((notvalue & 0x3ff) == 0) {
                                ir_node  *block     = get_nodes_block(node);
                                ir_node  *new_block = be_transform_node(block);
                                dbg_info *dbgi      = get_irn_dbg_info(node);
                                ir_node  *new_op2
                                        = new_bd_sparc_SetHi(NULL, new_block, NULL, notvalue);
                                ir_node  *new_op1   = be_transform_node(op1);
                                ir_node  *result
                                        = new_not_reg(dbgi, new_block, new_op1, new_op2);
                                return result;
                        }
                }
        }
        return gen_helper_binop_args(node, op1, op2,
                                                                 flags | MATCH_COMMUTATIVE,
                                                                 new_reg, new_imm);
}

static ir_node *gen_And(ir_node *node)
{
        return gen_helper_bitop(node,
                                new_bd_sparc_And_reg,
                                new_bd_sparc_And_imm,
                                new_bd_sparc_AndN_reg,
                                new_bd_sparc_AndN_imm,
                                MATCH_MODE_NEUTRAL);
}

static ir_node *gen_Or(ir_node *node)
{
        return gen_helper_bitop(node,
                                new_bd_sparc_Or_reg,
                                new_bd_sparc_Or_imm,
                                new_bd_sparc_OrN_reg,
                                new_bd_sparc_OrN_imm,
                                MATCH_MODE_NEUTRAL);
}

static ir_node *gen_Eor(ir_node *node)
{
        return gen_helper_bitop(node,
                                new_bd_sparc_Xor_reg,
                                new_bd_sparc_Xor_imm,
                                new_bd_sparc_XNor_reg,
                                new_bd_sparc_XNor_imm,
                                MATCH_MODE_NEUTRAL);
}

static ir_node *gen_Shl(ir_node *node)
{
        ir_mode *mode = get_irn_mode(node);
        if (get_mode_modulo_shift(mode) != 32)
                panic("modulo_shift!=32 not supported by sparc backend");
        return gen_helper_binop(node, MATCH_NONE, new_bd_sparc_Sll_reg, new_bd_sparc_Sll_imm);
}

static ir_node *gen_Shr(ir_node *node)
{
        ir_mode *mode = get_irn_mode(node);
        if (get_mode_modulo_shift(mode) != 32)
                panic("modulo_shift!=32 not supported by sparc backend");
        return gen_helper_binop(node, MATCH_NONE, new_bd_sparc_Srl_reg, new_bd_sparc_Srl_imm);
}

static ir_node *gen_Shrs(ir_node *node)
{
        ir_mode *mode = get_irn_mode(node);
        if (get_mode_modulo_shift(mode) != 32)
                panic("modulo_shift!=32 not supported by sparc backend");
        return gen_helper_binop(node, MATCH_NONE, new_bd_sparc_Sra_reg, new_bd_sparc_Sra_imm);
}

/**
 * Transforms a Minus node.
 */
static ir_node *gen_Minus(ir_node *node)
{
        ir_mode  *mode = get_irn_mode(node);
        ir_node  *op;
        ir_node  *block;
        ir_node  *new_op;
        ir_node  *zero;
        dbg_info *dbgi;

        if (mode_is_float(mode)) {
                return gen_helper_unfpop(node, mode, new_bd_sparc_fneg_s,
                                         new_bd_sparc_fneg_d, new_bd_sparc_fneg_q);
        }
        block  = be_transform_node(get_nodes_block(node));
        dbgi   = get_irn_dbg_info(node);
        op     = get_Minus_op(node);
        new_op = be_transform_node(op);
        zero   = get_g0(get_irn_irg(node));
        return new_bd_sparc_Sub_reg(dbgi, block, zero, new_op);
}

/**
 * Create an entity for a given (floating point) tarval
 */
static ir_entity *create_float_const_entity(ir_tarval *tv)
{
        const arch_env_t *arch_env = be_get_irg_arch_env(current_ir_graph);
        sparc_isa_t      *isa      = (sparc_isa_t*) arch_env;
        ir_entity        *entity   = (ir_entity*) pmap_get(isa->constants, tv);
        ir_initializer_t *initializer;
        ir_mode          *mode;
        ir_type          *type;
        ir_type          *glob;

        if (entity != NULL)
                return entity;

        mode   = get_tarval_mode(tv);
        type   = get_type_for_mode(mode);
        glob   = get_glob_type();
        entity = new_entity(glob, id_unique("C%u"), type);
        set_entity_visibility(entity, ir_visibility_private);
        add_entity_linkage(entity, IR_LINKAGE_CONSTANT);

        initializer = create_initializer_tarval(tv);
        set_entity_initializer(entity, initializer);

        pmap_insert(isa->constants, tv, entity);
        return entity;
}

static ir_node *gen_float_const(dbg_info *dbgi, ir_node *block, ir_tarval *tv)
{
        ir_entity *entity = create_float_const_entity(tv);
        ir_node   *hi     = new_bd_sparc_SetHi(dbgi, block, entity, 0);
        ir_node   *mem    = get_irg_no_mem(current_ir_graph);
        ir_mode   *mode   = get_tarval_mode(tv);
        ir_node   *new_op
                = create_ldf(dbgi, block, hi, mem, mode, entity, 0, false);
        ir_node   *proj   = new_r_Proj(new_op, mode, pn_sparc_Ldf_res);

        set_irn_pinned(new_op, op_pin_state_floats);
        return proj;
}

static ir_node *create_int_const(ir_node *block, int32_t value)
{
        if (value == 0) {
                ir_graph *irg = get_irn_irg(block);
                return get_g0(irg);
        } else if (sparc_is_value_imm_encodeable(value)) {
                ir_graph *irg = get_irn_irg(block);
                return new_bd_sparc_Or_imm(NULL, block, get_g0(irg), NULL, value);
        } else {
                ir_node *hi = new_bd_sparc_SetHi(NULL, block, NULL, value);
                if ((value & 0x3ff) != 0) {
                        return new_bd_sparc_Or_imm(NULL, block, hi, NULL, value & 0x3ff);
                } else {
                        return hi;
                }
        }
}

static ir_node *gen_Const(ir_node *node)
{
        ir_node   *block = be_transform_node(get_nodes_block(node));
        ir_mode   *mode  = get_irn_mode(node);
        dbg_info  *dbgi  = get_irn_dbg_info(node);
        ir_tarval *tv    = get_Const_tarval(node);
        int32_t    val;

        if (mode_is_float(mode)) {
                return gen_float_const(dbgi, block, tv);
        }
        val = (int32_t)get_tarval_long(tv);
        assert((long)val == get_tarval_long(tv));
        return create_int_const(block, val);
}

static ir_node *gen_Switch(ir_node *node)
{
        dbg_info              *dbgi         = get_irn_dbg_info(node);
        ir_node               *block        = get_nodes_block(node);
        ir_node               *new_block    = be_transform_node(block);
        ir_graph              *irg          = get_irn_irg(block);
        ir_node               *selector     = get_Switch_selector(node);
        ir_node               *new_selector = be_transform_node(selector);
        const ir_switch_table *table        = get_Switch_table(node);
        unsigned               n_outs       = get_Switch_n_outs(node);
        ir_entity             *entity;
        ir_node               *table_address;
        ir_node               *idx;
        ir_node               *load;
        ir_node               *address;

        table = ir_switch_table_duplicate(irg, table);

        /* switch with smaller mode not implemented yet */
        assert(get_mode_size_bits(get_irn_mode(selector)) == 32);

        entity = new_entity(NULL, id_unique("TBL%u"), get_unknown_type());
        set_entity_visibility(entity, ir_visibility_private);
        add_entity_linkage(entity, IR_LINKAGE_CONSTANT);

        /* construct base address */
        table_address = make_address(dbgi, new_block, entity, 0);
        /* scale index */
        idx = new_bd_sparc_Sll_imm(dbgi, new_block, new_selector, NULL, 2);
        /* load from jumptable */
        load = new_bd_sparc_Ld_reg(dbgi, new_block, table_address, idx,
                                   get_irg_no_mem(current_ir_graph),
                                   mode_gp);
        address = new_r_Proj(load, mode_gp, pn_sparc_Ld_res);

        return new_bd_sparc_SwitchJmp(dbgi, new_block, address, n_outs, table, entity);
}

static ir_node *gen_Cond(ir_node *node)
{
        ir_node    *selector = get_Cond_selector(node);
        ir_node    *cmp_left;
        ir_mode    *cmp_mode;
        ir_node    *block;
        ir_node    *flag_node;
        ir_relation relation;
        dbg_info   *dbgi;

        /* note: after lower_mode_b we are guaranteed to have a Cmp input */
        block       = be_transform_node(get_nodes_block(node));
        dbgi        = get_irn_dbg_info(node);
        cmp_left    = get_Cmp_left(selector);
        cmp_mode    = get_irn_mode(cmp_left);
        flag_node   = be_transform_node(selector);
        relation    = get_Cmp_relation(selector);
        if (mode_is_float(cmp_mode)) {
                return new_bd_sparc_fbfcc(dbgi, block, flag_node, relation);
        } else {
                bool is_unsigned = !mode_is_signed(cmp_mode);
                return new_bd_sparc_Bicc(dbgi, block, flag_node, relation, is_unsigned);
        }
}

/**
 * transform Cmp
 */
static ir_node *gen_Cmp(ir_node *node)
{
        ir_node *op1      = get_Cmp_left(node);
        ir_node *op2      = get_Cmp_right(node);
        ir_mode *cmp_mode = get_irn_mode(op1);
        assert(get_irn_mode(op2) == cmp_mode);

        if (mode_is_float(cmp_mode)) {
                ir_node  *block   = be_transform_node(get_nodes_block(node));
                dbg_info *dbgi    = get_irn_dbg_info(node);
                ir_node  *new_op1 = be_transform_node(op1);
                ir_node  *new_op2 = be_transform_node(op2);
                unsigned  bits    = get_mode_size_bits(cmp_mode);
                if (bits == 32) {
                        return new_bd_sparc_fcmp_s(dbgi, block, new_op1, new_op2, cmp_mode);
                } else if (bits == 64) {
                        return new_bd_sparc_fcmp_d(dbgi, block, new_op1, new_op2, cmp_mode);
                } else {
                        assert(bits == 128);
                        return new_bd_sparc_fcmp_q(dbgi, block, new_op1, new_op2, cmp_mode);
                }
        }

        /* when we compare a bitop like and,or,... with 0 then we can directly use
         * the bitopcc variant.
         * Currently we only do this when we're the only user of the node...
         */
        if (is_Const(op2) && is_Const_null(op2) && get_irn_n_edges(op1) == 1) {
                if (is_And(op1)) {
                        return gen_helper_bitop(op1,
                                                new_bd_sparc_AndCCZero_reg,
                                                new_bd_sparc_AndCCZero_imm,
                                                new_bd_sparc_AndNCCZero_reg,
                                                new_bd_sparc_AndNCCZero_imm,
                                                MATCH_NONE);
                } else if (is_Or(op1)) {
                        return gen_helper_bitop(op1,
                                                new_bd_sparc_OrCCZero_reg,
                                                new_bd_sparc_OrCCZero_imm,
                                                new_bd_sparc_OrNCCZero_reg,
                                                new_bd_sparc_OrNCCZero_imm,
                                                MATCH_NONE);
                } else if (is_Eor(op1)) {
                        return gen_helper_bitop(op1,
                                                new_bd_sparc_XorCCZero_reg,
                                                new_bd_sparc_XorCCZero_imm,
                                                new_bd_sparc_XNorCCZero_reg,
                                                new_bd_sparc_XNorCCZero_imm,
                                                MATCH_NONE);
                } else if (is_Add(op1)) {
                        return gen_helper_binop(op1, MATCH_COMMUTATIVE,
                                                new_bd_sparc_AddCCZero_reg,
                                                new_bd_sparc_AddCCZero_imm);
                } else if (is_Sub(op1)) {
                        return gen_helper_binop(op1, MATCH_NONE,
                                                new_bd_sparc_SubCCZero_reg,
                                                new_bd_sparc_SubCCZero_imm);
                } else if (is_Mul(op1)) {
                        return gen_helper_binop(op1, MATCH_COMMUTATIVE,
                                                new_bd_sparc_MulCCZero_reg,
                                                new_bd_sparc_MulCCZero_imm);
                }
        }

        /* integer compare */
        return gen_helper_binop_args(node, op1, op2, MATCH_NONE,
                                     new_bd_sparc_Cmp_reg, new_bd_sparc_Cmp_imm);
}

/**
 * Transforms a SymConst node.
 */
static ir_node *gen_SymConst(ir_node *node)
{
        ir_entity *entity    = get_SymConst_entity(node);
        dbg_info  *dbgi      = get_irn_dbg_info(node);
        ir_node   *block     = get_nodes_block(node);
        ir_node   *new_block = be_transform_node(block);
        return make_address(dbgi, new_block, entity, 0);
}

static ir_node *create_fftof(dbg_info *dbgi, ir_node *block, ir_node *op,
                             ir_mode *src_mode, ir_mode *dst_mode)
{
        unsigned src_bits = get_mode_size_bits(src_mode);
        unsigned dst_bits = get_mode_size_bits(dst_mode);
        if (src_bits == 32) {
                if (dst_bits == 64) {
                        return new_bd_sparc_fftof_s_d(dbgi, block, op, src_mode, dst_mode);
                } else {
                        assert(dst_bits == 128);
                        return new_bd_sparc_fftof_s_q(dbgi, block, op, src_mode, dst_mode);
                }
        } else if (src_bits == 64) {
                if (dst_bits == 32) {
                        return new_bd_sparc_fftof_d_s(dbgi, block, op, src_mode, dst_mode);
                } else {
                        assert(dst_bits == 128);
                        return new_bd_sparc_fftof_d_q(dbgi, block, op, src_mode, dst_mode);
                }
        } else {
                assert(src_bits == 128);
                if (dst_bits == 32) {
                        return new_bd_sparc_fftof_q_s(dbgi, block, op, src_mode, dst_mode);
                } else {
                        assert(dst_bits == 64);
                        return new_bd_sparc_fftof_q_d(dbgi, block, op, src_mode, dst_mode);
                }
        }
}

static ir_node *create_ftoi(dbg_info *dbgi, ir_node *block, ir_node *op,
                            ir_mode *src_mode)
{
        ir_node  *ftoi;
        unsigned  bits = get_mode_size_bits(src_mode);
        if (bits == 32) {
                ftoi = new_bd_sparc_fftoi_s(dbgi, block, op, src_mode);
        } else if (bits == 64) {
                ftoi = new_bd_sparc_fftoi_d(dbgi, block, op, src_mode);
        } else {
                assert(bits == 128);
                ftoi = new_bd_sparc_fftoi_q(dbgi, block, op, src_mode);
        }

        {
        ir_graph *irg   = get_irn_irg(block);
        ir_node  *sp    = get_irg_frame(irg);
        ir_node  *nomem = get_irg_no_mem(irg);
        ir_node  *stf   = create_stf(dbgi, block, ftoi, sp, nomem, src_mode,
                                     NULL, 0, true);
        ir_node  *ld    = new_bd_sparc_Ld_imm(dbgi, block, sp, stf, mode_gp,
                                              NULL, 0, true);
        ir_node  *res   = new_r_Proj(ld, mode_gp, pn_sparc_Ld_res);
        set_irn_pinned(stf, op_pin_state_floats);
        set_irn_pinned(ld, op_pin_state_floats);
        return res;
        }
}

static ir_node *create_itof(dbg_info *dbgi, ir_node *block, ir_node *op,
                            ir_mode *dst_mode)
{
        ir_graph *irg   = get_irn_irg(block);
        ir_node  *sp    = get_irg_frame(irg);
        ir_node  *nomem = get_irg_no_mem(irg);
        ir_node  *st    = new_bd_sparc_St_imm(dbgi, block, op, sp, nomem,
                                              mode_gp, NULL, 0, true);
        ir_node  *ldf   = new_bd_sparc_Ldf_s(dbgi, block, sp, st, mode_fp,
                                             NULL, 0, true);
        ir_node  *res   = new_r_Proj(ldf, mode_fp, pn_sparc_Ldf_res);
        unsigned  bits  = get_mode_size_bits(dst_mode);
        set_irn_pinned(st, op_pin_state_floats);
        set_irn_pinned(ldf, op_pin_state_floats);

        if (bits == 32) {
                return new_bd_sparc_fitof_s(dbgi, block, res, dst_mode);
        } else if (bits == 64) {
                return new_bd_sparc_fitof_d(dbgi, block, res, dst_mode);
        } else {
                assert(bits == 128);
                return new_bd_sparc_fitof_q(dbgi, block, res, dst_mode);
        }
}

static ir_node *gen_Conv(ir_node *node)
{
        ir_node  *block    = be_transform_node(get_nodes_block(node));
        ir_node  *op       = get_Conv_op(node);
        ir_mode  *src_mode = get_irn_mode(op);
        ir_mode  *dst_mode = get_irn_mode(node);
        dbg_info *dbgi     = get_irn_dbg_info(node);
        ir_node  *new_op;

        int src_bits = get_mode_size_bits(src_mode);
        int dst_bits = get_mode_size_bits(dst_mode);

        if (src_mode == mode_b)
                panic("ConvB not lowered %+F", node);

        if (src_mode == dst_mode)
                return be_transform_node(op);

        if (mode_is_float(src_mode) || mode_is_float(dst_mode)) {
                assert((src_bits <= 64 && dst_bits <= 64) && "quad FP not implemented");

                new_op = be_transform_node(op);
                if (mode_is_float(src_mode)) {
                        if (mode_is_float(dst_mode)) {
                                /* float -> float conv */
                                return create_fftof(dbgi, block, new_op, src_mode, dst_mode);
                        } else {
                                /* float -> int conv */
                                if (!mode_is_signed(dst_mode))
                                        panic("float to unsigned not implemented yet");
                                return create_ftoi(dbgi, block, new_op, src_mode);
                        }
                } else {
                        /* int -> float conv */
                        if (src_bits < 32) {
                                new_op = gen_extension(dbgi, block, new_op, src_mode);
                        } else if (src_bits == 32 && !mode_is_signed(src_mode)) {
                                panic("unsigned to float not lowered!");
                        }
                        return create_itof(dbgi, block, new_op, dst_mode);
                }
        } else { /* complete in gp registers */
                int min_bits;
                ir_mode *min_mode;

                if (src_bits == dst_bits || dst_mode == mode_b) {
                        /* kill unnecessary conv */
                        return be_transform_node(op);
                }

                if (src_bits < dst_bits) {
                        min_bits = src_bits;
                        min_mode = src_mode;
                } else {
                        min_bits = dst_bits;
                        min_mode = dst_mode;
                }

                if (upper_bits_clean(op, min_mode)) {
                        return be_transform_node(op);
                }
                new_op = be_transform_node(op);

                if (mode_is_signed(min_mode)) {
                        return gen_sign_extension(dbgi, block, new_op, min_bits);
                } else {
                        return gen_zero_extension(dbgi, block, new_op, min_bits);
                }
        }
}

static ir_node *gen_Unknown(ir_node *node)
{
        /* just produce a 0 */
        ir_mode *mode = get_irn_mode(node);
        if (mode_is_float(mode)) {
                ir_node *block = be_transform_node(get_nodes_block(node));
                return gen_float_const(NULL, block, get_mode_null(mode));
        } else if (mode_needs_gp_reg(mode)) {
                ir_graph *irg = get_irn_irg(node);
                return get_g0(irg);
        }

        panic("Unexpected Unknown mode");
}

/**
 * transform the start node to the prolog code
 */
static ir_node *gen_Start(ir_node *node)
{
        ir_graph  *irg           = get_irn_irg(node);
        ir_entity *entity        = get_irg_entity(irg);
        ir_type   *function_type = get_entity_type(entity);
        ir_node   *block         = get_nodes_block(node);
        ir_node   *new_block     = be_transform_node(block);
        dbg_info  *dbgi          = get_irn_dbg_info(node);
        struct obstack *obst     = be_get_be_obst(irg);
        const arch_register_req_t *req;
        size_t     n_outs;
        ir_node   *start;
        size_t     i;
        size_t     o;

        /* start building list of start constraints */
        assert(obstack_object_size(obst) == 0);

        /* calculate number of outputs */
        n_outs = 4; /* memory, g0, g7, sp */
        if (!current_cconv->omit_fp)
                ++n_outs; /* framepointer */
        /* function parameters */
        n_outs += current_cconv->n_param_regs;
        /* callee saves */
        if (current_cconv->omit_fp) {
                n_outs += ARRAY_SIZE(omit_fp_callee_saves);
        }

        start = new_bd_sparc_Start(dbgi, new_block, n_outs);

        o = 0;

        /* first output is memory */
        start_mem_offset = o;
        arch_set_irn_register_req_out(start, o, arch_no_register_req);
        ++o;

        /* the zero register */
        start_g0_offset = o;
        req = be_create_reg_req(obst, &sparc_registers[REG_G0],
                                arch_register_req_type_ignore);
        arch_set_irn_register_req_out(start, o, req);
        arch_set_irn_register_out(start, o, &sparc_registers[REG_G0]);
        ++o;

        /* g7 is used for TLS data */
        start_g7_offset = o;
        req = be_create_reg_req(obst, &sparc_registers[REG_G7],
                                arch_register_req_type_ignore);
        arch_set_irn_register_req_out(start, o, req);
        arch_set_irn_register_out(start, o, &sparc_registers[REG_G7]);
        ++o;

        /* we need an output for the stackpointer */
        start_sp_offset = o;
        req = be_create_reg_req(obst, sp_reg,
                        arch_register_req_type_produces_sp | arch_register_req_type_ignore);
        arch_set_irn_register_req_out(start, o, req);
        arch_set_irn_register_out(start, o, sp_reg);
        ++o;

        if (!current_cconv->omit_fp) {
                start_fp_offset = o;
                req = be_create_reg_req(obst, fp_reg, arch_register_req_type_ignore);
                arch_set_irn_register_req_out(start, o, req);
                arch_set_irn_register_out(start, o, fp_reg);
                ++o;
        }

        /* function parameters in registers */
        start_params_offset = o;
        for (i = 0; i < get_method_n_params(function_type); ++i) {
                const reg_or_stackslot_t *param = &current_cconv->parameters[i];
                const arch_register_t    *reg0  = param->reg0;
                const arch_register_t    *reg1  = param->reg1;
                if (reg0 != NULL) {
                        arch_set_irn_register_req_out(start, o, reg0->single_req);
                        arch_set_irn_register_out(start, o, reg0);
                        ++o;
                }
                if (reg1 != NULL) {
                        arch_set_irn_register_req_out(start, o, reg1->single_req);
                        arch_set_irn_register_out(start, o, reg1);
                        ++o;
                }
        }
        /* we need the values of the callee saves (Note: non omit-fp mode has no
         * callee saves) */
        start_callee_saves_offset = o;
        if (current_cconv->omit_fp) {
                size_t n_callee_saves = ARRAY_SIZE(omit_fp_callee_saves);
                size_t c;
                for (c = 0; c < n_callee_saves; ++c) {
                        const arch_register_t *reg = omit_fp_callee_saves[c];
                        arch_set_irn_register_req_out(start, o, reg->single_req);
                        arch_set_irn_register_out(start, o, reg);
                        ++o;
                }
        }
        assert(n_outs == o);

        return start;
}

static ir_node *get_initial_sp(ir_graph *irg)
{
        if (start_sp == NULL) {
                ir_node *start = get_irg_start(irg);
                start_sp = new_r_Proj(start, mode_gp, start_sp_offset);
        }
        return start_sp;
}

static ir_node *get_initial_fp(ir_graph *irg)
{
        if (start_fp == NULL) {
                ir_node *start = get_irg_start(irg);
                start_fp = new_r_Proj(start, mode_gp, start_fp_offset);
        }
        return start_fp;
}

static ir_node *get_initial_mem(ir_graph *irg)
{
        if (start_mem == NULL) {
                ir_node *start = get_irg_start(irg);
                start_mem = new_r_Proj(start, mode_M, start_mem_offset);
        }
        return start_mem;
}

static ir_node *get_stack_pointer_for(ir_node *node)
{
        /* get predecessor in stack_order list */
        ir_node *stack_pred = be_get_stack_pred(stackorder, node);
        ir_node *stack;

        if (stack_pred == NULL) {
                /* first stack user in the current block. We can simply use the
                 * initial sp_proj for it */
                ir_graph *irg = get_irn_irg(node);
                return get_initial_sp(irg);
        }

        be_transform_node(stack_pred);
        stack = (ir_node*)pmap_get(node_to_stack, stack_pred);
        if (stack == NULL) {
                return get_stack_pointer_for(stack_pred);
        }

        return stack;
}

/**
 * transform a Return node into epilogue code + return statement
 */
static ir_node *gen_Return(ir_node *node)
{
        ir_node  *block     = get_nodes_block(node);
        ir_graph *irg       = get_irn_irg(node);
        ir_node  *new_block = be_transform_node(block);
        dbg_info *dbgi      = get_irn_dbg_info(node);
        ir_node  *mem       = get_Return_mem(node);
        ir_node  *new_mem   = be_transform_node(mem);
        ir_node  *sp        = get_stack_pointer_for(node);
        size_t    n_res     = get_Return_n_ress(node);
        struct obstack *be_obst = be_get_be_obst(irg);
        ir_node  *bereturn;
        ir_node **in;
        const arch_register_req_t **reqs;
        size_t    i;
        size_t    p;
        size_t    n_ins;

        /* estimate number of return values */
        n_ins = 2 + n_res; /* memory + stackpointer, return values */
        if (current_cconv->omit_fp)
                n_ins += ARRAY_SIZE(omit_fp_callee_saves);

        in   = ALLOCAN(ir_node*, n_ins);
        reqs = OALLOCN(be_obst, const arch_register_req_t*, n_ins);
        p    = 0;

        in[p]   = new_mem;
        reqs[p] = arch_no_register_req;
        ++p;

        in[p]   = sp;
        reqs[p] = sp_reg->single_req;
        ++p;

        /* result values */
        for (i = 0; i < n_res; ++i) {
                ir_node                  *res_value     = get_Return_res(node, i);
                ir_node                  *new_res_value = be_transform_node(res_value);
                const reg_or_stackslot_t *slot          = &current_cconv->results[i];
                assert(slot->req1 == NULL);
                in[p]   = new_res_value;
                reqs[p] = slot->req0;
                ++p;
        }
        /* callee saves */
        if (current_cconv->omit_fp) {
                ir_node  *start          = get_irg_start(irg);
                size_t    n_callee_saves = ARRAY_SIZE(omit_fp_callee_saves);
                for (i = 0; i < n_callee_saves; ++i) {
                        const arch_register_t *reg   = omit_fp_callee_saves[i];
                        ir_mode               *mode  = reg->reg_class->mode;
                        ir_node               *value
                                        = new_r_Proj(start, mode, i + start_callee_saves_offset);
                        in[p]   = value;
                        reqs[p] = reg->single_req;
                        ++p;
                }
        }
        assert(p == n_ins);

        bereturn = new_bd_sparc_Return_reg(dbgi, new_block, n_ins, in);
        arch_set_irn_register_reqs_in(bereturn, reqs);

        return bereturn;
}

static ir_node *bitcast_int_to_float(dbg_info *dbgi, ir_node *block,
                                     ir_node *value0, ir_node *value1)
{
        ir_graph *irg   = current_ir_graph;
        ir_node  *sp    = get_irg_frame(irg);
        ir_node  *nomem = get_irg_no_mem(irg);
        ir_node  *st    = new_bd_sparc_St_imm(dbgi, block, value0, sp, nomem,
                                              mode_gp, NULL, 0, true);
        ir_mode  *mode;
        ir_node  *ldf;
        ir_node  *mem;
        set_irn_pinned(st, op_pin_state_floats);

        if (value1 != NULL) {
                ir_node *st1 = new_bd_sparc_St_imm(dbgi, block, value1, sp, nomem,
                                                   mode_gp, NULL, 4, true);
                ir_node *in[2] = { st, st1 };
                ir_node *sync  = new_r_Sync(block, 2, in);
                set_irn_pinned(st1, op_pin_state_floats);
                mem  = sync;
                mode = mode_fp2;
        } else {
                mem  = st;
                mode = mode_fp;
        }

        ldf = create_ldf(dbgi, block, sp, mem, mode, NULL, 0, true);
        set_irn_pinned(ldf, op_pin_state_floats);

        return new_r_Proj(ldf, mode, pn_sparc_Ldf_res);
}

static void bitcast_float_to_int(dbg_info *dbgi, ir_node *block,
                                 ir_node *value, ir_mode *float_mode,
                                 ir_node **result)
{
        int bits = get_mode_size_bits(float_mode);
        if (is_Const(value)) {
                ir_tarval *tv = get_Const_tarval(value);
                int32_t val = get_tarval_sub_bits(tv, 0)         |
                              (get_tarval_sub_bits(tv, 1) << 8)  |
                              (get_tarval_sub_bits(tv, 2) << 16) |
                              (get_tarval_sub_bits(tv, 3) << 24);
                result[0] = create_int_const(block, val);
                if (bits == 64) {
                        int32_t val = get_tarval_sub_bits(tv, 4)         |
                                                  (get_tarval_sub_bits(tv, 5) << 8)  |
                                                  (get_tarval_sub_bits(tv, 6) << 16) |
                                                  (get_tarval_sub_bits(tv, 7) << 24);
                        result[1] = create_int_const(block, val);
                } else {
                        assert(bits == 32);
                        result[1] = NULL;
                }
        } else {
                ir_graph *irg   = current_ir_graph;
                ir_node  *stack = get_irg_frame(irg);
                ir_node  *nomem = get_irg_no_mem(irg);
                ir_node  *new_value = be_transform_node(value);
                ir_node  *stf   = create_stf(dbgi, block, new_value, stack, nomem,
                                             float_mode, NULL, 0, true);
                ir_node  *ld;
                set_irn_pinned(stf, op_pin_state_floats);

                ld = new_bd_sparc_Ld_imm(dbgi, block, stack, stf, mode_gp, NULL, 0, true);
                set_irn_pinned(ld, op_pin_state_floats);
                result[0] = new_r_Proj(ld, mode_gp, pn_sparc_Ld_res);

                if (bits == 64) {
                        ir_node *ld2 = new_bd_sparc_Ld_imm(dbgi, block, stack, stf, mode_gp,
                                                                                           NULL, 4, true);
                        set_irn_pinned(ld, op_pin_state_floats);
                        result[1] = new_r_Proj(ld2, mode_gp, pn_sparc_Ld_res);

                        arch_add_irn_flags(ld, (arch_irn_flags_t)sparc_arch_irn_flag_needs_64bit_spillslot);
                        arch_add_irn_flags(ld2, (arch_irn_flags_t)sparc_arch_irn_flag_needs_64bit_spillslot);
                } else {
                        assert(bits == 32);
                        result[1] = NULL;
                }
        }
}

static ir_node *gen_Call(ir_node *node)
{
        ir_graph        *irg          = get_irn_irg(node);
        ir_node         *callee       = get_Call_ptr(node);
        ir_node         *block        = get_nodes_block(node);
        ir_node         *new_block    = be_transform_node(block);
        ir_node         *mem          = get_Call_mem(node);
        ir_node         *new_mem      = be_transform_node(mem);
        dbg_info        *dbgi         = get_irn_dbg_info(node);
        ir_type         *type         = get_Call_type(node);
        size_t           n_params     = get_Call_n_params(node);
        size_t           n_ress       = get_method_n_ress(type);
        /* max inputs: memory, callee, register arguments */
        ir_node        **sync_ins     = ALLOCAN(ir_node*, n_params);
        struct obstack  *obst         = be_get_be_obst(irg);
        calling_convention_t *cconv
                = sparc_decide_calling_convention(type, NULL);
        size_t           n_param_regs = cconv->n_param_regs;
        /* param-regs + mem + stackpointer + callee */
        unsigned         max_inputs   = 3 + n_param_regs;
        ir_node        **in           = ALLOCAN(ir_node*, max_inputs);
        const arch_register_req_t **in_req
                = OALLOCNZ(obst, const arch_register_req_t*, max_inputs);
        int              in_arity     = 0;
        int              sync_arity   = 0;
        int              n_caller_saves
                = rbitset_popcount(cconv->caller_saves, N_SPARC_REGISTERS);
        ir_entity       *entity       = NULL;
        ir_node         *new_frame    = get_stack_pointer_for(node);
        bool             aggregate_return
                = get_method_calling_convention(type) & cc_compound_ret;
        ir_node         *incsp;
        int              mem_pos;
        ir_node         *res;
        size_t           p;
        size_t           r;
        int              i;
        int              o;
        int              out_arity;

        assert(n_params == get_method_n_params(type));

        /* construct arguments */

        /* memory input */
        in_req[in_arity] = arch_no_register_req;
        mem_pos          = in_arity;
        ++in_arity;

        /* stack pointer input */
        /* construct an IncSP -> we have to always be sure that the stack is
         * aligned even if we don't push arguments on it */
        incsp = be_new_IncSP(sp_reg, new_block, new_frame,
                             cconv->param_stack_size, 1);
        in_req[in_arity] = sp_reg->single_req;
        in[in_arity]     = incsp;
        ++in_arity;

        /* parameters */
        for (p = 0; p < n_params; ++p) {
                ir_node                  *value      = get_Call_param(node, p);
                const reg_or_stackslot_t *param      = &cconv->parameters[p];
                ir_type                  *param_type = get_method_param_type(type, p);
                ir_mode                  *mode       = get_type_mode(param_type);
                ir_node                  *partial_value;
                ir_node                  *new_values[2];
                ir_node                  *str;
                int                       offset;

                if (mode_is_float(mode) && param->reg0 != NULL) {
                        unsigned size_bits = get_mode_size_bits(mode);
                        assert(size_bits <= 64);
                        bitcast_float_to_int(dbgi, new_block, value, mode, new_values);
                } else {
                        ir_node *new_value = be_transform_node(value);
                        new_values[0] = new_value;
                        new_values[1] = NULL;
                }

                /* put value into registers */
                if (param->reg0 != NULL) {
                        in[in_arity]     = new_values[0];
                        in_req[in_arity] = param->reg0->single_req;
                        ++in_arity;
                        if (new_values[1] == NULL)
                                continue;
                }
                if (param->reg1 != NULL) {
                        assert(new_values[1] != NULL);
                        in[in_arity]     = new_values[1];
                        in_req[in_arity] = param->reg1->single_req;
                        ++in_arity;
                        continue;
                }

                /* we need a store if we're here */
                if (new_values[1] != NULL) {
                        partial_value = new_values[1];
                        mode          = mode_gp;
                } else {
                        partial_value = new_values[0];
                }

                /* we need to skip over our save area when constructing the call
                 * arguments on stack */
                offset = param->offset + SPARC_MIN_STACKSIZE;

                if (mode_is_float(mode)) {
                        str = create_stf(dbgi, new_block, partial_value, incsp, new_mem,
                                         mode, NULL, offset, true);
                } else {
                        str = new_bd_sparc_St_imm(dbgi, new_block, partial_value, incsp,
                                                  new_mem, mode, NULL, offset, true);
                }
                set_irn_pinned(str, op_pin_state_floats);
                sync_ins[sync_arity++] = str;
        }

        /* construct memory input */
        if (sync_arity == 0) {
                in[mem_pos] = new_mem;
        } else if (sync_arity == 1) {
                in[mem_pos] = sync_ins[0];
        } else {
                in[mem_pos] = new_rd_Sync(NULL, new_block, sync_arity, sync_ins);
        }

        if (is_SymConst(callee)) {
                entity = get_SymConst_entity(callee);
        } else {
                in[in_arity]     = be_transform_node(callee);
                in_req[in_arity] = sparc_reg_classes[CLASS_sparc_gp].class_req;
                ++in_arity;
        }
        assert(in_arity <= (int)max_inputs);

        /* outputs:
         *  - memory
         *  - results
         *  - caller saves
         */
        out_arity = 1 + cconv->n_reg_results + n_caller_saves;

        /* create call node */
        if (entity != NULL) {
                res = new_bd_sparc_Call_imm(dbgi, new_block, in_arity, in, out_arity,
                                            entity, 0, aggregate_return);
        } else {
                res = new_bd_sparc_Call_reg(dbgi, new_block, in_arity, in, out_arity,
                                            aggregate_return);
        }
        arch_set_irn_register_reqs_in(res, in_req);

        /* create output register reqs */
        o = 0;
        arch_set_irn_register_req_out(res, o++, arch_no_register_req);
        /* add register requirements for the result regs */
        for (r = 0; r < n_ress; ++r) {
                const reg_or_stackslot_t  *result_info = &cconv->results[r];
                const arch_register_req_t *req         = result_info->req0;
                if (req != NULL) {
                        arch_set_irn_register_req_out(res, o++, req);
                }
                assert(result_info->req1 == NULL);
        }
        for (i = 0; i < N_SPARC_REGISTERS; ++i) {
                const arch_register_t *reg;
                if (!rbitset_is_set(cconv->caller_saves, i))
                        continue;
                reg = &sparc_registers[i];
                arch_set_irn_register_req_out(res, o++, reg->single_req);
        }
        assert(o == out_arity);

        /* copy pinned attribute */
        set_irn_pinned(res, get_irn_pinned(node));

        /* IncSP to destroy the call stackframe */
        incsp = be_new_IncSP(sp_reg, new_block, incsp, -cconv->param_stack_size, 0);
        /* if we are the last IncSP producer in a block then we have to keep
         * the stack value.
         * Note: This here keeps all producers which is more than necessary */
        add_irn_dep(incsp, res);
        keep_alive(incsp);

        pmap_insert(node_to_stack, node, incsp);

        sparc_free_calling_convention(cconv);
        return res;
}

static ir_node *gen_Sel(ir_node *node)
{
        dbg_info  *dbgi      = get_irn_dbg_info(node);
        ir_node   *block     = get_nodes_block(node);
        ir_node   *new_block = be_transform_node(block);
        ir_node   *ptr       = get_Sel_ptr(node);
        ir_node   *new_ptr   = be_transform_node(ptr);
        ir_entity *entity    = get_Sel_entity(node);

        /* must be the frame pointer all other sels must have been lowered
         * already */
        assert(is_Proj(ptr) && is_Start(get_Proj_pred(ptr)));

        return new_bd_sparc_FrameAddr(dbgi, new_block, new_ptr, entity, 0);
}

static ir_node *gen_Alloc(ir_node *node)
{
        dbg_info *dbgi       = get_irn_dbg_info(node);
        ir_node  *block      = get_nodes_block(node);
        ir_node  *new_block  = be_transform_node(block);
        ir_type  *type       = get_Alloc_type(node);
        ir_node  *size       = get_Alloc_count(node);
        ir_node  *stack_pred = get_stack_pointer_for(node);
        ir_node  *subsp;
        if (get_Alloc_where(node) != stack_alloc)
                panic("only stack-alloc supported in sparc backend (at %+F)", node);
        /* lowerer should have transformed all allocas to byte size */
        if (type != get_unknown_type() && get_type_size_bytes(type) != 1)
                panic("Found non-byte alloc in sparc backend (at %+F)", node);

        if (is_Const(size)) {
                ir_tarval *tv    = get_Const_tarval(size);
                long       sizel = get_tarval_long(tv);
                subsp = be_new_IncSP(sp_reg, new_block, stack_pred, sizel, 0);
                set_irn_dbg_info(subsp, dbgi);
        } else {
                ir_node *new_size = be_transform_node(size);
                subsp = new_bd_sparc_SubSP(dbgi, new_block, stack_pred, new_size);
                arch_set_irn_register(subsp, sp_reg);
        }

        /* if we are the last IncSP producer in a block then we have to keep
         * the stack value.
         * Note: This here keeps all producers which is more than necessary */
        keep_alive(subsp);

        pmap_insert(node_to_stack, node, subsp);
        /* the "result" is the unmodified sp value */
        return stack_pred;
}

static ir_node *gen_Proj_Alloc(ir_node *node)
{
        ir_node *alloc = get_Proj_pred(node);
        long     pn    = get_Proj_proj(node);

        switch ((pn_Alloc)pn) {
        case pn_Alloc_M: {
                ir_node *alloc_mem = get_Alloc_mem(alloc);
                return be_transform_node(alloc_mem);
        }
        case pn_Alloc_res: {
                ir_node *new_alloc = be_transform_node(alloc);
                return new_alloc;
        }
        case pn_Alloc_X_regular:
        case pn_Alloc_X_except:
                panic("sparc backend: exception output of alloc not supported (at %+F)",
                      node);
        }
        panic("sparc backend: invalid Proj->Alloc");
}

static ir_node *gen_Free(ir_node *node)
{
        dbg_info *dbgi       = get_irn_dbg_info(node);
        ir_node  *block      = get_nodes_block(node);
        ir_node  *new_block  = be_transform_node(block);
        ir_type  *type       = get_Free_type(node);
        ir_node  *size       = get_Free_count(node);
        ir_node  *mem        = get_Free_mem(node);
        ir_node  *new_mem    = be_transform_node(mem);
        ir_node  *stack_pred = get_stack_pointer_for(node);
        ir_node  *addsp;
        if (get_Alloc_where(node) != stack_alloc)
                panic("only stack-alloc supported in sparc backend (at %+F)", node);
        /* lowerer should have transformed all allocas to byte size */
        if (type != get_unknown_type() && get_type_size_bytes(type) != 1)
                panic("Found non-byte alloc in sparc backend (at %+F)", node);

        if (is_Const(size)) {
                ir_tarval *tv    = get_Const_tarval(size);
                long       sizel = get_tarval_long(tv);
                addsp = be_new_IncSP(sp_reg, new_block, stack_pred, -sizel, 0);
                set_irn_dbg_info(addsp, dbgi);
        } else {
                ir_node *new_size = be_transform_node(size);
                addsp = new_bd_sparc_AddSP(dbgi, new_block, stack_pred, new_size);
                arch_set_irn_register(addsp, sp_reg);
        }

        /* if we are the last IncSP producer in a block then we have to keep
         * the stack value.
         * Note: This here keeps all producers which is more than necessary */
        keep_alive(addsp);

        pmap_insert(node_to_stack, node, addsp);
        /* the "result" is the unmodified sp value */
        return new_mem;
}

static const arch_register_req_t float1_req = {
        arch_register_req_type_normal,
        &sparc_reg_classes[CLASS_sparc_fp],
        NULL,
        0,
        0,
        1
};
static const arch_register_req_t float2_req = {
        arch_register_req_type_normal | arch_register_req_type_aligned,
        &sparc_reg_classes[CLASS_sparc_fp],
        NULL,
        0,
        0,
        2
};
static const arch_register_req_t float4_req = {
        arch_register_req_type_normal | arch_register_req_type_aligned,
        &sparc_reg_classes[CLASS_sparc_fp],
        NULL,
        0,
        0,
        4
};


static const arch_register_req_t *get_float_req(ir_mode *mode)
{
        unsigned bits = get_mode_size_bits(mode);

        assert(mode_is_float(mode));
        if (bits == 32) {
                return &float1_req;
        } else if (bits == 64) {
                return &float2_req;
        } else {
                assert(bits == 128);
                return &float4_req;
        }
}

/**
 * Transform some Phi nodes
 */
static ir_node *gen_Phi(ir_node *node)
{
        const arch_register_req_t *req;
        ir_node  *block = be_transform_node(get_nodes_block(node));
        ir_graph *irg   = current_ir_graph;
        dbg_info *dbgi  = get_irn_dbg_info(node);
        ir_mode  *mode  = get_irn_mode(node);
        ir_node  *phi;

        if (mode_needs_gp_reg(mode)) {
                /* we shouldn't have any 64bit stuff around anymore */
                assert(get_mode_size_bits(mode) <= 32);
                /* all integer operations are on 32bit registers now */
                mode = mode_gp;
                req  = sparc_reg_classes[CLASS_sparc_gp].class_req;
        } else if (mode_is_float(mode)) {
                req  = get_float_req(mode);
        } else {
                req = arch_no_register_req;
        }

        /* phi nodes allow loops, so we use the old arguments for now
         * and fix this later */
        phi = new_ir_node(dbgi, irg, block, op_Phi, mode, get_irn_arity(node), get_irn_in(node) + 1);
        copy_node_attr(irg, node, phi);
        be_duplicate_deps(node, phi);
        arch_set_irn_register_req_out(phi, 0, req);
        be_enqueue_preds(node);
        return phi;
}

/**
 * Transform a Proj from a Load.
 */
static ir_node *gen_Proj_Load(ir_node *node)
{
        ir_node  *load     = get_Proj_pred(node);
        ir_node  *new_load = be_transform_node(load);
        dbg_info *dbgi     = get_irn_dbg_info(node);
        long      pn       = get_Proj_proj(node);

        /* renumber the proj */
        switch (get_sparc_irn_opcode(new_load)) {
        case iro_sparc_Ld:
                /* handle all gp loads equal: they have the same proj numbers. */
                if (pn == pn_Load_res) {
                        return new_rd_Proj(dbgi, new_load, mode_gp, pn_sparc_Ld_res);
                } else if (pn == pn_Load_M) {
                        return new_rd_Proj(dbgi, new_load, mode_M, pn_sparc_Ld_M);
                }
                break;
        case iro_sparc_Ldf:
                if (pn == pn_Load_res) {
                        const sparc_load_store_attr_t *attr
                                = get_sparc_load_store_attr_const(new_load);
                        ir_mode *mode = attr->load_store_mode;
                        return new_rd_Proj(dbgi, new_load, mode, pn_sparc_Ldf_res);
                } else if (pn == pn_Load_M) {
                        return new_rd_Proj(dbgi, new_load, mode_M, pn_sparc_Ld_M);
                }
                break;
        default:
                break;
        }
        panic("Unsupported Proj from Load");
}

static ir_node *gen_Proj_Store(ir_node *node)
{
        ir_node  *store     = get_Proj_pred(node);
        ir_node  *new_store = be_transform_node(store);
        long      pn        = get_Proj_proj(node);

        /* renumber the proj */
        switch (get_sparc_irn_opcode(new_store)) {
        case iro_sparc_St:
                if (pn == pn_Store_M) {
                        return new_store;
                }
                break;
        case iro_sparc_Stf:
                if (pn == pn_Store_M) {
                        return new_store;
                }
                break;
        default:
                break;
        }
        panic("Unsupported Proj from Store");
}

/**
 * Transform the Projs from a Cmp.
 */
static ir_node *gen_Proj_Cmp(ir_node *node)
{
        (void) node;
        panic("not implemented");
}

/**
 * transform Projs from a Div
 */
static ir_node *gen_Proj_Div(ir_node *node)
{
        ir_node  *pred     = get_Proj_pred(node);
        ir_node  *new_pred = be_transform_node(pred);
        long      pn       = get_Proj_proj(node);
        ir_mode  *res_mode;

        if (is_sparc_SDiv(new_pred) || is_sparc_UDiv(new_pred)) {
                res_mode = mode_gp;
        } else if (is_sparc_fdiv(new_pred)) {
                res_mode = get_Div_resmode(pred);
        } else {
                panic("sparc backend: Div transformed to something unexpected: %+F",
                      new_pred);
        }
        assert((int)pn_sparc_SDiv_res == (int)pn_sparc_UDiv_res);
        assert((int)pn_sparc_SDiv_M   == (int)pn_sparc_UDiv_M);
        assert((int)pn_sparc_SDiv_res == (int)pn_sparc_fdiv_res);
        assert((int)pn_sparc_SDiv_M   == (int)pn_sparc_fdiv_M);
        switch (pn) {
        case pn_Div_res:
                return new_r_Proj(new_pred, res_mode, pn_sparc_SDiv_res);
        case pn_Div_M:
                return new_r_Proj(new_pred, mode_gp, pn_sparc_SDiv_M);
        default:
                break;
        }
        panic("Unsupported Proj from Div");
}

static ir_node *get_frame_base(ir_graph *irg)
{
        if (frame_base == NULL) {
                if (current_cconv->omit_fp) {
                        frame_base = get_initial_sp(irg);
                } else {
                        frame_base = get_initial_fp(irg);
                }
        }
        return frame_base;
}

static ir_node *gen_Proj_Start(ir_node *node)
{
        ir_node *block     = get_nodes_block(node);
        ir_node *new_block = be_transform_node(block);
        long     pn        = get_Proj_proj(node);
        /* make sure prolog is constructed */
        be_transform_node(get_Proj_pred(node));

        switch ((pn_Start) pn) {
        case pn_Start_X_initial_exec:
                /* exchange ProjX with a jump */
                return new_bd_sparc_Ba(NULL, new_block);
        case pn_Start_M: {
                ir_graph *irg = get_irn_irg(node);
                return get_initial_mem(irg);
        }
        case pn_Start_T_args:
                return new_r_Bad(get_irn_irg(block), mode_T);
        case pn_Start_P_frame_base:
                return get_frame_base(get_irn_irg(block));
        }
        panic("Unexpected start proj: %ld\n", pn);
}

static ir_node *gen_Proj_Proj_Start(ir_node *node)
{
        long      pn        = get_Proj_proj(node);
        ir_node  *block     = get_nodes_block(node);
        ir_graph *irg       = get_irn_irg(node);
        ir_node  *new_block = be_transform_node(block);
        ir_node  *args      = get_Proj_pred(node);
        ir_node  *start     = get_Proj_pred(args);
        ir_node  *new_start = be_transform_node(start);
        const reg_or_stackslot_t *param;

        /* Proj->Proj->Start must be a method argument */
        assert(get_Proj_proj(get_Proj_pred(node)) == pn_Start_T_args);

        param = &current_cconv->parameters[pn];

        if (param->reg0 != NULL) {
                /* argument transmitted in register */
                const arch_register_t *reg      = param->reg0;
                ir_mode               *reg_mode = reg->reg_class->mode;
                long                   new_pn   = param->reg_offset + start_params_offset;
                ir_node               *value    = new_r_Proj(new_start, reg_mode, new_pn);
                bool                   is_float = false;

                {
                        ir_entity *entity      = get_irg_entity(irg);
                        ir_type   *method_type = get_entity_type(entity);
                        if (pn < (long)get_method_n_params(method_type)) {
                                ir_type *param_type = get_method_param_type(method_type, pn);
                                ir_mode *mode       = get_type_mode(param_type);
                                is_float = mode_is_float(mode);
                        }
                }

                if (is_float) {
                        const arch_register_t *reg1 = param->reg1;
                        ir_node *value1 = NULL;

                        if (reg1 != NULL) {
                                ir_mode *reg1_mode = reg1->reg_class->mode;
                                value1 = new_r_Proj(new_start, reg1_mode, new_pn+1);
                        } else if (param->entity != NULL) {
                                ir_node *fp  = get_initial_fp(irg);
                                ir_node *mem = get_initial_mem(irg);
                                ir_node *ld  = new_bd_sparc_Ld_imm(NULL, new_block, fp, mem,
                                                                   mode_gp, param->entity,
                                                                   0, true);
                                value1 = new_r_Proj(ld, mode_gp, pn_sparc_Ld_res);
                        }

                        /* convert integer value to float */
                        value = bitcast_int_to_float(NULL, new_block, value, value1);
                }
                return value;
        } else {
                /* argument transmitted on stack */
                ir_node *mem  = get_initial_mem(irg);
                ir_mode *mode = get_type_mode(param->type);
                ir_node *base = get_frame_base(irg);
                ir_node *load;
                ir_node *value;

                if (mode_is_float(mode)) {
                        load  = create_ldf(NULL, new_block, base, mem, mode,
                                           param->entity, 0, true);
                        value = new_r_Proj(load, mode_fp, pn_sparc_Ldf_res);
                } else {
                        load  = new_bd_sparc_Ld_imm(NULL, new_block, base, mem, mode,
                                                    param->entity, 0, true);
                        value = new_r_Proj(load, mode_gp, pn_sparc_Ld_res);
                }
                set_irn_pinned(load, op_pin_state_floats);

                return value;
        }
}

static ir_node *gen_Proj_Call(ir_node *node)
{
        long     pn        = get_Proj_proj(node);
        ir_node *call      = get_Proj_pred(node);
        ir_node *new_call  = be_transform_node(call);

        switch ((pn_Call) pn) {
        case pn_Call_M:
                return new_r_Proj(new_call, mode_M, 0);
        case pn_Call_X_regular:
        case pn_Call_X_except:
        case pn_Call_T_result:
                break;
        }
        panic("Unexpected Call proj %ld\n", pn);
}

static ir_node *gen_Proj_Proj_Call(ir_node *node)
{
        long                  pn            = get_Proj_proj(node);
        ir_node              *call          = get_Proj_pred(get_Proj_pred(node));
        ir_node              *new_call      = be_transform_node(call);
        ir_type              *function_type = get_Call_type(call);
        calling_convention_t *cconv
                = sparc_decide_calling_convention(function_type, NULL);
        const reg_or_stackslot_t  *res  = &cconv->results[pn];
        ir_mode                   *mode = get_irn_mode(node);
        long                       new_pn = 1 + res->reg_offset;

        assert(res->req0 != NULL && res->req1 == NULL);
        if (mode_needs_gp_reg(mode)) {
                mode = mode_gp;
        }
        sparc_free_calling_convention(cconv);

        return new_r_Proj(new_call, mode, new_pn);
}

/**
 * Transform a Proj node.
 */
static ir_node *gen_Proj(ir_node *node)
{
        ir_node *pred = get_Proj_pred(node);

        switch (get_irn_opcode(pred)) {
        case iro_Alloc:
                return gen_Proj_Alloc(node);
        case iro_Store:
                return gen_Proj_Store(node);
        case iro_Load:
                return gen_Proj_Load(node);
        case iro_Call:
                return gen_Proj_Call(node);
        case iro_Cmp:
                return gen_Proj_Cmp(node);
        case iro_Switch:
        case iro_Cond:
                return be_duplicate_node(node);
        case iro_Div:
                return gen_Proj_Div(node);
        case iro_Start:
                return gen_Proj_Start(node);
        case iro_Proj: {
                ir_node *pred_pred = get_Proj_pred(pred);
                if (is_Call(pred_pred)) {
                        return gen_Proj_Proj_Call(node);
                } else if (is_Start(pred_pred)) {
                        return gen_Proj_Proj_Start(node);
                }
                /* FALLTHROUGH */
        }
        default:
                if (is_sparc_AddCC_t(pred)) {
                        return gen_Proj_AddCC_t(node);
                } else if (is_sparc_SubCC_t(pred)) {
                        return gen_Proj_SubCC_t(node);
                }
                panic("code selection didn't expect Proj after %+F\n", pred);
        }
}

/**
 * transform a Jmp
 */
static ir_node *gen_Jmp(ir_node *node)
{
        ir_node  *block     = get_nodes_block(node);
        ir_node  *new_block = be_transform_node(block);
        dbg_info *dbgi      = get_irn_dbg_info(node);

        return new_bd_sparc_Ba(dbgi, new_block);
}

/**
 * configure transformation callbacks
 */
static void sparc_register_transformers(void)
{
        be_start_transform_setup();

        be_set_transform_function(op_Add,          gen_Add);
        be_set_transform_function(op_Alloc,        gen_Alloc);
        be_set_transform_function(op_And,          gen_And);
        be_set_transform_function(op_Call,         gen_Call);
        be_set_transform_function(op_Cmp,          gen_Cmp);
        be_set_transform_function(op_Cond,         gen_Cond);
        be_set_transform_function(op_Const,        gen_Const);
        be_set_transform_function(op_Conv,         gen_Conv);
        be_set_transform_function(op_Div,          gen_Div);
        be_set_transform_function(op_Eor,          gen_Eor);
        be_set_transform_function(op_Free,         gen_Free);
        be_set_transform_function(op_Jmp,          gen_Jmp);
        be_set_transform_function(op_Load,         gen_Load);
        be_set_transform_function(op_Minus,        gen_Minus);
        be_set_transform_function(op_Mul,          gen_Mul);
        be_set_transform_function(op_Mulh,         gen_Mulh);
        be_set_transform_function(op_Not,          gen_Not);
        be_set_transform_function(op_Or,           gen_Or);
        be_set_transform_function(op_Phi,          gen_Phi);
        be_set_transform_function(op_Proj,         gen_Proj);
        be_set_transform_function(op_Return,       gen_Return);
        be_set_transform_function(op_Sel,          gen_Sel);
        be_set_transform_function(op_Shl,          gen_Shl);
        be_set_transform_function(op_Shr,          gen_Shr);
        be_set_transform_function(op_Shrs,         gen_Shrs);
        be_set_transform_function(op_Start,        gen_Start);
        be_set_transform_function(op_Store,        gen_Store);
        be_set_transform_function(op_Sub,          gen_Sub);
        be_set_transform_function(op_Switch,       gen_Switch);
        be_set_transform_function(op_SymConst,     gen_SymConst);
        be_set_transform_function(op_Unknown,      gen_Unknown);

        be_set_transform_function(op_sparc_AddX_t, gen_AddX_t);
        be_set_transform_function(op_sparc_AddCC_t,gen_AddCC_t);
        be_set_transform_function(op_sparc_Save,   be_duplicate_node);
        be_set_transform_function(op_sparc_SubX_t, gen_SubX_t);
        be_set_transform_function(op_sparc_SubCC_t,gen_SubCC_t);
}

/**
 * Transform a Firm graph into a SPARC graph.
 */
void sparc_transform_graph(ir_graph *irg)
{
        ir_entity *entity = get_irg_entity(irg);
        ir_type   *frame_type;

        sparc_register_transformers();

        node_to_stack = pmap_create();

        mode_gp    = sparc_reg_classes[CLASS_sparc_gp].mode;
        mode_fp    = sparc_reg_classes[CLASS_sparc_fp].mode;
        mode_fp2   = mode_D;
        //mode_fp4 = ?
        mode_flags = sparc_reg_classes[CLASS_sparc_flags_class].mode;
        assert(sparc_reg_classes[CLASS_sparc_fpflags_class].mode == mode_flags);

        start_mem  = NULL;
        start_g0   = NULL;
        start_g7   = NULL;
        start_sp   = NULL;
        start_fp   = NULL;
        frame_base = NULL;

        stackorder = be_collect_stacknodes(irg);
        current_cconv
                = sparc_decide_calling_convention(get_entity_type(entity), irg);
        if (sparc_variadic_fixups(irg, current_cconv)) {
                sparc_free_calling_convention(current_cconv);
                current_cconv
                        = sparc_decide_calling_convention(get_entity_type(entity), irg);
        }
        sparc_create_stacklayout(irg, current_cconv);
        be_add_parameter_entity_stores(irg);

        be_transform_graph(irg, NULL);

        be_free_stackorder(stackorder);
        sparc_free_calling_convention(current_cconv);

        frame_type = get_irg_frame_type(irg);
        if (get_type_state(frame_type) == layout_undefined)
                default_layout_compound_type(frame_type);

        pmap_destroy(node_to_stack);
        node_to_stack = NULL;

        be_add_missing_keeps(irg);

        /* do code placement, to optimize the position of constants */
        place_code(irg);
        /* backend expects outedges to be always on */
        edges_assure(irg);
}

void sparc_init_transform(void)
{
        FIRM_DBG_REGISTER(dbg, "firm.be.sparc.transform");
}